Takuya Shimazaki

Conditional ablation of Stat3 or Socs3 discloses a dual role for reactive astrocytes after spinal cord injury.

In the injured central nervous system (CNS), reactive astrocytes form a glial scar and are considered to be detrimental for axonal regeneration, but their function remains elusive. Here we show that reactive astrocytes have a crucial role in wound healing and functional recovery by using mice with a selective deletion of the protein signal transducer and activator of transcription 3 (Stat3) or the protein suppressor of cytokine signaling 3 (Socs3) under the control of the Nes promoter-enhancer (Nes-Stat3−/−, Nes-Socs3−/−). Reactive astrocytes in Nes-Stat3−/− mice showed limited migration and resulted in markedly widespread infiltration of inflammatory cells, neural disruption and demyelination with severe motor deficits after contusive spinal cord injury (SCI). On the contrary, we observed rapid migration of reactive astrocytes to seclude inflammatory cells, enhanced contraction of lesion area and notable improvement in functional recovery in Nes-Socs3−/− mice. These results suggest that Stat3 is a key regulator of reactive astrocytes in the healing process after SCI, providing a potential target for intervention in the treatment of CNS injury.

Transient inhibition of BMP signaling by Noggin induces cardiomyocyte differentiation of mouse embryonic stem cells.

Embryonic stem (ES) cells are a promising source of cardiomyocytes, but clinical application of ES cells has been hindered by the lack of reliable selective differentiation methods. Differentiation into any lineage is partly dependent on the regulatory mechanisms of normal early development. Although several signals, including bone morphogenetic protein (BMP), Wnt and FGF, are involved in heart development, scarce evidence is available about the exact signals that mediate cardiomyocyte differentiation. While investigating the involvement of BMP signaling in early heart formation in the mouse, we found that the BMP antagonist Noggin is transiently but strongly expressed in the heart-forming region during gastrulation and acts at the level of induction of mesendoderm to establish conditions conducive to cardiogenesis. We applied this finding to develop an effective protocol for obtaining cardiomyocytes from mouse ES cells by inhibition of BMP signaling.

Cardiac neural crest cells contribute to the dormant multipotent stem cell in the mammalian heart

Arodent cardiac side population cell fraction formed clonal spheroids in serum-free medium, which expressed nestin, Musashi-1, and multi-drug resistance transporter gene 1, markers of undifferentiated neural precursor cells. These markers were lost following differentiation, and were replaced by the expression of neuron-, glial-, smooth muscle cell–, or cardiomyocyte-specific proteins. Cardiosphere-derived cells transplanted into chick embryos migrated to the truncus arteriosus and cardiac outflow tract and contributed to dorsal root ganglia, spinal nerves, and aortic smooth muscle cells. Lineage studies using double transgenic mice encoding protein 0–Cre/Floxed-EGFP revealed undifferentiated and differentiated neural crest-derived cells in the fetal myocardium. Undifferentiated cells expressed GATA-binding protein 4 and nestin, but not actinin, whereas the differentiated cells were identified as cardiomyocytes. These results suggest that cardiac neural crest-derived cells migrate into the heart, remain there as dormant multipotent stem cells—and under the right conditions—differentiate into cardiomyocytes and typical neural crest-derived cells, including neurons, glia, and smooth muscle.

Blockade of interleukin-6 receptor suppresses reactive astrogliosis and ameliorates functional recovery in experimental spinal cord injury.

Endogenous neural stem/progenitor cells (NSPCs) have recently been shown to differentiate exclusively into astrocytes, the cells that are involved in glial scar formation after spinal cord injury (SCI). The microenvironment of the spinal cord, especially the inflammatory cytokines that dramatically increase in the acute phase at the injury site, is considered to be an important cause of inhibitory mechanism of neuronal differentiation following SCI. Interleukin‐6 (IL‐6), which has been demonstrated to induce NSPCs to undergo astrocytic differentiation selectively through the JAK/STAT pathway in vitro, has also been demonstrated to play a critical role as a proinflammatory cytokine and to be associated with secondary tissue damage in SCI. In this study, we assessed the efficacy of rat anti‐mouse IL‐6 receptor monoclonal antibody (MR16‐1) in the treatment of acute SCI in mice. Immediately after contusive SCI with a modified NYU impactor, mice were intraperitoneally injected with a single dose of MR16‐1 (100 μg/g body weight), the lesions were assessed histologically, and the functional recovery was evaluated. MR16‐1 not only suppressed the astrocytic diffentiation‐promoting effect of IL‐6 signaling in vitro but inhibited the development of astrogliosis after SCI in vivo. MR16‐1 also decreased the number of invading inflammatory cells and the severity of connective tissue scar formation. In addition, we observed significant functional recovery in the mice treated with MR16‐1 compared with control mice. These findings suggest that neutralization of IL‐6 signaling in the acute phase of SCI represents an attractive option for the treatment of SCI.

Requirement for COUP-TFI and II in the temporal specification of neural stem cells in CNS development

In the developing CNS, subtypes of neurons and glial cells are generated according to a schedule that is defined by cell-intrinsic mechanisms that function at the progenitor-cell level. However, no critical molecular switch for the temporal specification of CNS progenitor cells has been identified. We found that chicken ovalbumin upstream promoter-transcription factor I and II (Coup-tfI and Coup-tfII, also known as Nr2f1 and Nr2f2) are required for the temporal specification of neural stem/progenitor cells (NSPCs), including their acquisition of gliogenic competence, as demonstrated by their responsiveness to gliogenic cytokines. COUP-TFI and II are transiently co-expressed in the ventricular zone of the early embryonic CNS. The double knockdown of Coup-tfI/II in embryonic stem cell (ESC)-derived NSPCs and the developing mouse forebrain caused sustained neurogenesis and the prolonged generation of early-born neurons. These findings reveal a part of the timer mechanisms for generating diverse types of neurons and glial cells during CNS development.

Human neural stem/progenitor cells, expanded in long‐term neurosphere culture, promote functional recovery after focal ischemia in Mongolian gerbils

Transplantation of human neural stem cells (NSCs) is a promising potential therapy for neurologic dysfunctions after the hyperacute stage of stroke in humans, but large amounts of human NSCs must be expanded in long‐term culture for such therapy. To determine their possible therapeutic potential for human stroke, human fetal neural stem/progenitor cells (NSPCs) (i.e., neurosphere‐forming cells) were isolated originally from forebrain tissues of one human fetus, and expanded in long‐term neurosphere culture (exceeding 24 weeks), then xenografted into the lesioned areas in the brains of Mongolian gerbils 4 days after focal ischemia. Sensorimotor and cognitive functions were evaluated during the 4 weeks after transplantation. The total infarction volume in the NSPC‐grafted animals was significantly lower than that in controls. Approximately 8% of the grafted NSPCs survived, mainly in areas of selective neuronal death, and were costained with antibodies against neuronal nuclei antibody (NeuN), microtubule associated protein (MAP‐2), glial fibrillary acidic protein (GFAP), and anti‐2′3′ cyclic nucleotide 3′‐phosphodiesterase (CNPase). Synaptic structures between NSPCs‐derived neurons and host neurons were observed. Furthermore, gradual improvement of neurologic functions was observed clearly in the NSPC‐grafted animals, compared to that in controls. Human NSPCs, even from long‐term culture, remarkably improved neurologic functions after focal ischemia in the Mongolian gerbil, and maintained their abilities to migrate around the infarction, differentiate into mature neurons, and form synapses with host neuronal circuits. These results indicate that in vitro‐expanded human neurosphere cells are a potential source for transplantable material for treatment of stroke.

Spatiotemporal Recapitulation of Central Nervous System Development by Murine Embryonic Stem Cell-Derived Neural Stem/Progenitor Cells

Neural stem/progenitor cells (NS/PCs) can generate a wide variety of neural cells. However, their fates are generally restricted, depending on the time and location of NS/PC origin. Here we demonstrate that we can recapitulate the spatiotemporal regulation of central nervous system (CNS) development in vitro by using a neurosphere‐based culture system of embryonic stem (ES) cell‐derived NS/PCs. This ES cell‐derived neurosphere system enables the efficient derivation of highly neurogenic fibroblast growth factor‐responsive NS/PCs with early temporal identities and high cell‐fate plasticity. Over repeated passages, these NS/PCs exhibit temporal progression, becoming epidermal growth factor‐responsive gliogenic NS/PCs with late temporal identities; this change is accompanied by an alteration in the epigenetic status of the glial fibrillary acidic protein promoter, similar to that observed in the developing brain. Moreover, the rostrocaudal and dorsoventral spatial identities of the NS/PCs can be successfully regulated by sequential administration of several morphogens. These NS/PCs can differentiate into early‐born projection neurons, including cholinergic, catecholaminergic, serotonergic, and motor neurons, that exhibit action potentials in vitro. Finally, these NS/PCs differentiate into neurons that form synaptic contacts with host neurons after their transplantation into wild‐type and disease model animals. Thus, this culture system can be used to obtain specific neurons from ES cells, is a simple and powerful tool for investigating the underlying mechanisms of CNS development, and is applicable to regenerative treatment for neurological disorders.

GFRα3, a Component of the Artemin Receptor, Is Required for Migration and Survival of the Superior Cervical Ganglion

Abstract GFRα3 is a component of the receptor for the neurotrophic factor artemin. The role of GFRα3 in nervous system development was examined by generating mice in which the Gfrα3 gene was disrupted. The Gfrα3 −/− mice exhibited severe defects in the superior cervical ganglion (SCG), whereas other ganglia appeared normal. SCG precursor cells in the mutant embryos failed to migrate to the correct position, and they subsequently failed to innervate the target organs. In wild-type embryos, Gfrα3 was expressed in migrating SCG precursors, and artemin was expressed in and near the SCG. After birth, SCG neurons in the mutant mice underwent progressive cell death. These observations suggest that GFRα3-mediated signaling is required both for the rostral migration of SCG precursors and for the survival of mature SCG neurons.

Flow cytometric analysis of neural stem cells in the developing and adult mouse brain

Despite recent progress in the neural stem cell biology, their cellular characteristics have not been described well. We investigated various characteristics of neural stem cells (NSCs) in vivo during CNS development, using FACS to identify the NSCs. We first examined stage‐dependent changes in the physical parameters, using forward scatter (FSC) and side scatter (SSC) profiles, of NSCs from the developing striatum, where they appear to be active throughout the life of mammals. NSCs were divided into several fractions according to their FSC/SSC profile. With development, their number decreased in the FSChigh fractions but increased in the FSClow/SSChigh fraction, whereas NSCs were significantly concentrated in the fraction containing the largest cells (about 20 μm in diameter) at any stage, which were mostly the cells with the highest nestin‐enhancer activity. Furthermore, we demonstrated that, at all stages examined, the “side population” (SP), defined as the Hoechst 33342 low/negative fraction, which is known to be a stem cell‐enriched population in bone marrow, was also enriched for Notch1‐positive immature neural cells (about 60%) from the developing striatum. However, these immature SP cells were not detected in the large‐cell fraction, however, but were concentrated instead in the FSClow/mid fractions. FACS analysis showed that SP cells from adults were included to some extent in the CD24low/PNAlow fraction, where NSCs were greatly concentrated. Collectively, the characteristics of NSCs were not uniform and changed developmentally.

Isolation and transplantation of dopaminergic neurons generated from mouse embryonic stem cells

Embryonic stem (ES) cells differentiate into dopamine (DA)-producing neurons when co-cultured with PA6 stromal cells, but the resulting cultures contain a variety of unidentified cells. In order to label live DA neurons in mixed populations, we introduced a GFP reporter under the control of the tyrosine hydroxylase (TH) gene promoter into ES cells. GFP expression was observed in TH-immunoreactive cells that differentiated from the ES cells that carried the TH-GFP reporter gene. DA neurons expressing GFP were sorted from the mixed cell population by fluorescence-activated cell sorting of cells exhibiting GFP fluorescence, and the sorted GFP(+) cells obtained were transplanted into a rat model of Parkinsons disease. Some of these cells survived and innervated the host striatum, resulting in a partial recovery from parkinsonian behavioral defects. This strategy of isolation and transplantation of ES-cell-derived DA neurons should be useful for cellular and molecular studies of DA neurons and for clinical application in the treatment of Parkinsons disease.